Rotary press and lint sampler



Feb. 25, 1964 s. w. SINCLAIR 3,122,089

ROTARY PRESS AND LINT SAMPLER Filed May 16. 1961 s Sheets-Sheet 1 PHEJJ Z/A/T FL 0E 51 JAM/ 1 E ATTOR/VEKS G/A/ MACH/IVE Feb. 25, 1964 s. w. SINCLAIR 3, ,08

, ROTARYPRESS AND LINT SAMPLER Filed May 16, 1961 8 Sheets-Sheet 2 CWT/7N5 ATTORNEY;

Feb. 25, 1964 Filed May 16, 1961 S. W. SINCLAIR ROTARY PRESS AND LINT SAMPLER 8 Sheets-Sheet 3 l .llllm INV EN TOR.

W M. M6442. 4522 487 1 Feb. 25, 1964 s. w. SINCLAIR 3,122,089

ROTARY PRESS AND LINT SAMPLER Filed May 16, 1961 8 Sheets-Sheet 4 IN V EN TOR. m a/w Mia/z BY asw ixzwiz Feb. 25, 1964 s. w. SINCLAIR 3,122,089

ROTARY PRESS AND LINT SAMPLER Filed May 16. 1961 8 Sheets-Sheet 5 Jfuorz W J/flc/a/r y iIIgLENgOR. BY a W z/xfi w Feb. 25, 1964 s. w. SINCLAIR 3, 89

ROTARY PRESS AND LINT SAMPLER Filed May 16. 1961 8 Sheets-Sheet 6 MIA/M5110 a g I fiTZJW/U [L/[CT/ON Jfuar/ VV. J/nc/a/r INVENTOR. faunas M -lu W p 62%,) BY Zea-h. Q W

Feb. 25, 1964 s. w. SINCLAIR 3,122,039

ROTARY PRESS AND LINT SAMPLER Filed May 16. 1961 8 Sheets-Sheet 7 Jzuar I W //7 cl a/r INVENTOR.

Y 8,, 2 w B WM 4 $1514 ATTORNEYS Feb. 25, 1964 s. w. SINCLAIR ROTARY PRESS AND LINT SAMPLER 8 Sheets-Sheet 8 Filed May 16. 1961 Q X m mam v Q WQ I. Iii

Jfuarz I/V. J/nc/a/r INVENIUR. yM *7? 2 15 BY 7% 26mm Ma o/we: 4,. $3M $41K 2 AITQR/VEnS United States Patent Patented Feb. 25, 1954 Free Filed M sty 16, Hill, Ser. No. 119,473 9 Guitars. (Cl. lllll4} The present invention relates to an mproved rotary press and lint sampler and methods particularly useful in increasing the density of ginned cotton fibers and making a continuous sample of compressed cotton as it is being placed in a conventional press for baling.

Although the present invention is particularly described hereinafter with reference to cotton fibre, it will become apparent that the present invention is useful in increasing the density of any compressible fiber lint and making a continuous sample thereor". The present disclosure is directed, therefore, to a rotary press and sampler for cotton, but it will be understood that other fibers and lints are encompassed Within the scope hereof. To understand the theory of the present invention and the state of the cotton press art, a summary is given.

when raw cotton reaches the gin, it is first processed in a cotton gin to remove the seed and a great deal of the trash picned up with the bolls. The cotton fiber output of the cotton gin is typically called lint. The lint is very light, fiufi'y and loose, hence, for economy of transportation and storage, it is compressed to a higher density, and this compressed mass of cotton lint is called a bale. These bales are somewhat rectangular in shape for they are typically produced on platen presses.

Typically, gins produce either gin fiat bales or gin standard bales, although a very few gins produce a much denser bale cal ed the gin Hi-D (gin density). The gin fiat press costs approximately $8,609 at the present time and produces a bale having a density of about 15#/cu. ft. The gm standard press produces a bale havin a density of about ZO-Zfifi/cu. ft. and costs a great deal more-approximately $25,960 at the present time, even though the ale density has increased only 5- O#/cu. ft. The gin Hi-D press is a massive piece of equipment costing approximately $75,900 at the present time and produces a bale having a density of about 3235-7'.='/cu. ft.

To understand the reason why these various gin presses increase so rapidly in cost, reference is made to FIGURE 15 wherein an approximate pressure-density curve ab is shown for the compression of cotton. To produce a gin fiat bale, the press must exert a pressure of about 50,0897"? Thus, following the curve upwardly from a, the press exerts a force of 150,0S# at point e, which is equivalent to a density of about 25#/cu. it. Then, when the press is opened to permit tying of the compressed cotton with bands, the cotton expands along the line c. Z. Due to the lay of the lint the nature of cotton, once it has been killed or compressed, the density remains at some value, such as 7#/ cu. ft. (point 45) even without bands. However, with bands, the resultant density is about 15#/cu. ft. (point e on line cd). Hence to produce a gin flat bale of l#/cu. ft. density, the press must exert a force of 150,000# on an area approximately 28 in. x 55 in. Recornpression of previously killed or compressed cotton substantial dupl sates the expansion curve c(l up until the original compression curve is reached (point 0), and thereafter the cotton follows the original compression curve czb upwardly.

in a similar manner, to produce a gin standard bale of 2(li.='/ cu. ft. density, a total force or" about 660,009-# must be exerted, and to produce a gin Hi-D bale of 35#/cu. ft. density, a total force of 22,500,000# must be exerted. Further, the gin Hi-D press platen has an area of about 20 in. x 54 in. and the press stroke i pproxirnately 8 ft. 6 in. Thus, it is readily seen that the machines are huge, and extremely powerful, and accor ingly the price is prohibitive.

Nonetheless, if a quantity of cotton were available, the cost might be justified. Unfortunately, however, gins are typically located in small towns and the geographical area which a gin can economically serve is limited. So, very few gins can afford t e gin Hi-D press, even though it produces a more economically shipped and stored bale. Consequently, the majority of gins produce a gin flat bale which is sent to the compress for iurther ensification. At the compress more cotton is available, hence larger equipment is justified.

From the foregoing, it is seen that it would be very advantageous to provide a small press, simply made, relatively inexpensive, which is capable of exerting at least 2,006,660r't force on cotton lint in such a manner as will produce a very high density bale. Such a press could then be economically installed at the gin to provide bales for export and domestic use, and the need for the compress would be eliminated, except perhaps at a Warehouse. These, then are the general objects of the present invention.

Previously, presses have been suggested and built which produce a round bale or a long cylinder of cotton, by rol n g a continuous length of batting. Patented examples shoving these round bale presses are: Treese, 653,191; 'lreese, 938,706; Brown, 1,257,798; Mackenzie, 1,834,466; and Mackenzie, 1,881,774. The round bale so produced was quite effective from the ginners standpoint, but was unacceptable to the textile mills due to the matted fiber produced in the center of thebale.

The present invention is directed to a rotary press which incorporates a drum about which the cotton lint is wound and compressed. Thereafter, this compressed cotton hnt is removed from the drum and placed in a small banding press for the attachment of bands. The resultant bale is rectangular in crossection, and its density is superior to that of the gin Hi-D bale. The entire rotary press is quite small and the bale produced therefrom is uniform, Without matted fibers.

in addition to utilizing the present invention as a rotary press, a smaller version thereof is ideally suited for use as a lint sampler. Cotton is one or" the few commodities still purchased by samples. This necessitates hiring expert samplers in each cotton producing area to grade the baled cotton as to quality. It is customary for the sampler to cut the burlap protective cover on each bale and remove a large sample plug of cotton. This plug is then examined and graded, and it is assumed that the plug adequately represents the remainder of the bale. If the once plugged bale is not then sold, it will be left in a Warehouse until another potential buyer is found. Again the plugging and grading is repeated, until the bale is sold. By this time, it is not unusual for the price of the bale to decline because of its mangled condition after being repeatedly plugged.

Prior devices to solve this problem have been developed which intermittently remove bursts of cotton lint from the flue between the gin machine and the baling press, condense the lint, tramp it, and finally insert a dozen or so layers into a paper Wrapper. These devices Were developed by the US. Department of Agriculture. Because the cotton is sampled interrnittently, the sample does not contain a portion or all of the lint in the bale, nor does a cross-section of the paper-swapped sample represent a similar cross-section of the bale. Since the price or" the bale is determined by the quality of the sample, it is very advantageous to provide a truly representative sample. Such a sample should contain a portion of all of the fiber in the bale, it should be compressed as is the bale, it should have the same fiber lay,'and the bale should not be disturbed when grading the sample. The lint sampler of the present invention meets all of these requirements, and is additionally small, simple, easily repaired, and requires very little control equipment. Further, the lint sampler utilizes a smaller sample valve in the lint flue which opens only once.

The lint sampler of the present invention is directed to a rotary press which incorporates a drum about which the cotton lint is wound and compressed. Thereafter, the compressed cotton lint is removed from the drum and placed in a sample bag or paper wrapper. The lint sampler gathers and compresses cotton fiber virtually the entire time that the corresponding bale is being formed either on a rotary press or conventional platen press.

It is, therefore, an object of the present invention to provide a rotary press and lint sampler which has all of the advantages hereinbefore mentioned and overcomes the disadvantages of the prior devices.

Another object of the present invention is to provide a small press capable of exerting 2,000,G# force on cotton lint in such a manner as will produce a very high density bale with unmatted fibers.

Yet another object of the present invention is to provide a rotary press having a drum which produces a circular band of compressed fiber.

Another object is to provide a rotary press having a drum from which compressed fiber may be easily and readily removed, and converted into elongate batts for the formation of a rectangular cross-section bale or for insertion into a sample wrapper.

A still further object of the present invention is to provide a novel means for the removal of a compressed ring of fiber from the drum of a rotary press.

Another object of the present invention is to provide a rotary press whereby the pressure necessary to form a highly compressed fiber batt need be applied to only a small part of the fiber at any one time, thus substantially reducing the total force, size, and complexity of the press.

Another object of the present invention is to provide a fiber press which requires no surges of energy and which employs a mechanical drive with components familiar to glnners and without the need for fluid pressures and attendant oil stains.

Another object of the present invention is to provide a method of compressing a batt of fiber which is unmatted and very dense.

Still another object of the present invention is to pro vide a method of compressing a batt which includes winding the batt upon a drum and compressing the batt between the drum and a series of compression rollers disposed about the drum.

Yet another object of the present invention is to provide a method of compressing a loose fibrous batt which includes winding the batt upon a drum, compressing the batt betwen the drum and a series of compression rollers disposed about the drum and ejecting the compressed batt for insertion in a sack or wrapper as a sample or for placement on a small banding press for banding several compressed batts into a bale.

Other and further objects, features and advantages will be apparent from the following description of presently preferred embodiments of the invention, given for the purpose of disclosure, taken in conjunction with the accompanying drawings, where like character references designate like parts throughout the several views, and where:

FIGURE 1 is a schematic representation of the flow of cotton in a gin, showing the present invention utilized as a lint sampler,

FIGURE 2 is a schematic representation of one form of ejection mechanism for compressed batts of the present invention,

FIGURE 3 is a view similar to FIGURE 2 showing the compressed ring-like batt being cut,

FIGURE 4 is a view similar to FIGURE 2 showing the batt being ejected,

FIGURE 5 is a rear view of a lint sampler according to the present invention,

FIGURE 6 is a side view of the device of FIGURE 5,

FIGURE 7 is a front view of the device of FIGURE 5,

FIGURE 8 is a schematic representation of one form of drive for the compression rollers of the device of FIGURE 5,

FIGURE 9 is a partial sectional end view of a segmented drum and compression rollers of one form of the invention,

FIGURE 10 is a schematic representation of the device of FIGURE 9 showing the introduction of cotton fiber thereto,

FIGURE 11 is a view similar to FIGURE 10 showing the segmented drum retracted,

FIGURE 12 is a view similar to FIGURE 10 showing the ejection of a compressed batt,

FIGURE 13 is a partial sectional side view of the rotary press of FIGURE 9 showing in dotted lines the retracted position of the drum,

FIGURE 14 is a partial sectional side view of another form of drum for the rotary press of the present invention, and

FIGURE 15 is a pressure density curve of cotton fiber showing the effect of compression and expansion.

Generally, the apparatus of the invention comprises a drum whose circumference is surrounded by a series of compression rollers. In addition, means are provided for the ejection of a ring-like batt of compressed fiber, such as by cutting the ring or removing the drum, and then running the batt out.

The theory of the invention is quite readily seen by referring to FIGURE 15, and the prior discussion thereof hereinabove. Briefly, cotton fiber when compressed follows the curve 11-!) upwardly. This curve is derived from data obtained when compressing bales of cotton in hydraulic presses. As previously noted, if the cotton fiber is compressed until a certain pressure is reached, such as at c, and then the pressure is removed, the cotton gradually expands along the line cd. Therefore, the density has increased even though the pressure is removed, for the density at d is greater than that at a. Further, if the once compressed fiber is recompressed it substantially follows the curve dc until intersecting the original curve ab, hence the recompression curve would be dcb. A similar family of expansion and recompression curves exists all along the curve ab.

If the cotton fiber is compressed along ab to c, then removed from the press, it expands down to d. Thereupon, the compressed fiber (now a batt) is placed in a small press for banding and a comparatively small amount of pressure again applied (such as that indicated by the horizontal dashed line labeled band holding force) and the density is again increased to that at point 2. This may be conveniently done in a small conventional banding platen press.

Thus it is seen that the problem is to effect a substantial first compression along thecurve ab, with much smaller equipment than heretofore used. Therefore, the present invention applies a very high pressure to a small area of the cotton fiber by wrapping the cotton lint about a drum and compressing the lint between the drum and a series of rollers disposed about the drum. Thereupon, means are provided for the removal of the compressed ring of cotton from the rotary press. The discussion which follows is first directed to a lint sampler for combe used for grading a contemporaneously formed bale.

Then the discussion will turn to additional forms of the rotary press for particular use in bale forming instead of sampling, although all may be used interchangeably.

Referring now to FTGURE l, a generalized schematic view of the flow of cotton lint in a gin is shown. The trash is removed and the incoming cotton bolls are then deseeded in the conventional gin machine 2%. Then the cotton is conducted to the conventional gin press 22 through a lint due or conduit 24. The lint may be carried by a positive pressure (such as by blowers) or by a vacuum system, both of which are conventional, and a condenser 26 is used to remove the air and leave an uncompressed mat of fiber. This mat is built up in layers in a conventional gin press 22, and then compressed into a bale. A sample valve 28 is provided in the flue 24 for the removal of a sample oi cotton lint which will be made into a packaged compressed sample. A conventional sample valve 23 is shown in the patent to Gaus et al., No. 2,329,544. Leading from the valve 28 is a duct 39, which may be a ll xible hose, that carries a small part of the a' orne lint 32 to the li; t sample 3 The lint sampler includes condenser rollers 3-6, guide rollers immediately downstream from the condenser rollers 36, a drum 4t) surrounded by compression rollers Associated with drum 4%? is a means of removing the compressed bait, nereinaiter described. The cotton batt leaving the condenser rollers is shown as a mat defined by two solid lines for ease of explanation.

The condenser rollers 36 turn inwardly toward each other, as dicated by the arrows, and remove the air carries the lint 32. la a conventional manner, therefore, the condenser rollers 36 provide a loose batt fiber is fed to the guide rollers 38.

pression of the batt 44 and also the batt onto the drum 4% The drum 4%? rotates in a certain dire tron, such as that indicated by the arrow, an likewise the compression rollers 42 rotate wi subst ntially the same peripheral speed as the drurn in, so that batt d is fed and wound about the drum 4-3. The compression rollers are spaced from the periphery of the a small dist nce to allow the batt 44 to pass therehe veen. in a conventional manner, some or all of the compression rollers 52 may be knurled, toothed, splined, or the like to aid in winding the butt 44 upon the drum in a spiral manner, the successive layers of the batt 44 are built up on the drum 4%. As

thickness or" so wound batt increases, the compression rollers begin to compress the batt E4.

com ression of the wound batt continues until er the gin press 22 is full and the lint the lint flue stream from the valve 22%, or until the list sam ler is shut due to reaching its capacity, or the lint from the gin machine 2;"; is diverted through appropriate conventi nal m ans to a similar gin press ""1 and lint sampler 3a or a conventional accumulator (not s own). in any event, as a mere matter of design, the city oi the lint sampler 3 is designed so that the compression on the batt substantially equivalent to that of a normal bale being forrned in the gin press 22, tli desired co ression is designed to be reached at approximately the same time as the condenser 26 for the gin press 23 is shut down. There-tore, advantageously,

valve 23 is opened only once and remains open thereafter substantially the e tire time the bale is being formed in the gin press 22. "y seen, therefore, that the it is rea batt =3 compressed by the lint sampler 34 contains a sample portion of virtually all of the cotton in the bale, and also provides a batt id wndch is compressed in layers just as the bade. Further, the lay is similar to the bale and unrnatted, for compression occurs in only one direction.

Referring to FZGURE 15, it is seen that the pressure needed to form a high density bale increases rapidly. The pressure is, of course, defined as the force ivided by the area. Therefore, in a conventional platen press it it is necessary to produce 22,500,00G# force on a platen area of 20 in. x 54 in. to form a gin Hi-D bale, the resultant pressure needed is roughly 300,009 pounds per square foot (psi). Now, it the area of compression is substantially reduced and the resultant pressure needed remains the same, i.e., roughly 300,800 p.s.f., then the necessary force is likewise substantially reduced. Thus, if the area of compression is reduced to 20 in. x /1 in., the necessary force is reduced to roughly l0,000#, and the resultant pressure remains 300,000 psi In this manor, a substantial eduction in force has occurred, and the size of the press may be accordin ly reduced.

As shown in FTGURE the compression rollers 4.2 surround the drum i The bat; 454 being compressed is disposed therebetween. The theoretical area being con.- pressed is only the line of contact between the compression roller 42 and drum 4%, and this line is as long as the roller 42. with no appreciable width. The actual area, however, is the length of the roller and a finite width, and it is obvious that the highest pressure is exerted on the batt 4-4- at its intersection with a plane through the centers of the drum and roller in any event, the force necessary to compress the butt is reduced.

When the lint 32 coming from the valve 2?, is shut off, the batt -34 is immediately wound and compressed around the drum and becomes a ring of compressed cotton fiber. This ring must then be removed from the drum and converted into an elongate butt for insertion in a wrapper. Referring now to FIGURES 2-4, one means for doing so is shown. Briefly, this means comprises cutting the and running the batt 4e off of the drum.

One sector of the c rcumference of the drum 4 3* is composed or" a cutter as hav'ng the same v' as the drum 4%). The cutter 4-5 is pivoted about die ants and includes two cylindrical surfaces and 52. Surface 5% has the same radius as the drum ll so that when this surface Sll is e posed, the perimeter or" the drum 4% defines a circle, such as shown in 2. Surface 52-, however, is designed to bulge outwardly when exposed on the drum 4%, as in *TGURE 3, so that the spac between the compression roller 42 and the exposed surface 52 is l ss than that between the drum sion roller 4-2. Pivotably connecting link 54 and pivotably attached to is a crank :36. The crank 55% may be rotated through axis of the drum 4i To cut the batt 44 and r nove it from the list sampler 34, the rotation of the and compression llers 42 is stopped, with the cutter opposite compress n roller 42 1. Thereupon, one of tile compression rollers ted outwardly from the drum Then the roation of the compression rollers and is reversed. the same time, the crank 5% is rotated to move the -nl: 5% which rotates the cutter do about the axis r, the surface is w hdrawn into the dru the bulging surface :2 is exposed. Compare Y 2 and 3. Since compression roller is the only rot roller now contao the batt and since the spacing between the roller 42:: and the or do is reduced, the rotating roller 62:: tears or cuts the batt 4- along the width or" the drum 4-6, as shown in FIGURE 3.

Roller 42:: continues to rotate, and begins to rotate the drum through the bait 44. After a slight rota tion or" the drum lr'l, the crank is rotated to retract the bulging surf ce 52 and re-expose surface 5%, thereby making the surface of the drum a circular cylinder again, as shown in 4. The compression roller 52a immediately below the pivoted roller is now rotated in a dif$ti0l opposie to that of rollers 42a and 4217, so that the leading edge of the batt is ejected outwardly between roller 42b and roller its, as

' angle irons.

7 seen in FIGURE 4. After one revolution of the drum 4%, the batt 44 is completel ejected.

Thereupon, the ejected batt 44 is led through appropriate discharge rollers $8 (seen in FIGURE 7) and into a rectangular wrapper or sack 6 3. In a few seconds, the discharged cotton batt 4-4.- begins to expand and fills the sack oil. The sack 69 is then removed from the lint sampler 34, and the operation is complete. A sample batt has been made which contains a portion of virtually all of the lint which makes up the bale, the sample has been compressed in layers, the fiber lay resembles the bale and is unmatted, and the equipment utilized is relatively simple.

Now that the theory of operation and generalized schematics have been presented, an embodiment of the lint sampler 34 of the present invention will be discussed. A presently preferred embodiment is shown in FIGURES -7. Referring now to FEGURE 5, the lint sampler 34 generally includes a frame 62 on which are rotatably mounted the condenser roller pulleys 336 which are directly connected to the condenser rollers 35, the guide roller pulleys 138 which are directly connected to the guide rollers 38, the drum pulley ldtl which is connected to the drum 413, and the compression roller gears 142 which are connected to the compression rollers 42, all in a conventional manner. The condenser roller pulleys 136, guide roller pulleys 138, idler 64, adjustable idler 66, and a pulley 68 (shown in FEGURE 8) are interconnected by a belt 7%, in such a manner that the pulleys will rotate in the direction shown by the arrows when feeding a batt to the drum. The adjustable idler 66 is rotatably mounted on a plate 72 which is pivotably mounted at 74 on the frame 62. The plate 72 includes an arcuate slot 76 through which a bolt 78 is attached to the frame 62. When the bolt 7 8 is loosened, the plate 72 may be pivoted to tighten the belt 7%.

A pulley it is attached to the jack shaft 82 and connected by a belt 8 to a motor 86. The jack shaft 82 in turn moves the belt 83 to rotate the drum pulley 140, and therefore the drum 45?. Shown in FIGURE 7 is an appropriate drum gear 92 connected to the drum pulley 144) to drive the compression roller gears 142 and therefore the compression rollers 42. An identical drum gear 92 is shown in FIGURE 7. Surrounding the upper part of the condenser rollers 36, which cannot be seen in FIGURE 5 because of the condenser roller pulleys 136, is a seal 9% which is typically used in positive pressure type condensers. A similar seal 94 and the condenser rollers 36 are clearly shown in FIGURES 6 and 7.

Referring now to FIGURE 7, the front of the lint sampler 34 is shown. The drum gear 92 engages the compression roller gears 142. Since the compression rollers 42 are closely spaced, as previously shown in FIG- URE 1, alternate compression rollers 42 are driven from opposite sides, although they may be driven from the same side (Treese 653,191, supra). Mounted on the upper part of the frame 62 are the condenser rollers 36, and immediately below them are the guide rollers 33, shown in dotted lines. The motor 26 is also shown in dotted lines, as are the discharge rollers 58.

Pivotably mounted on the frame 62 is a lever 94 to which are attached eccentric cams 96 and crank 93. The cams 96 are utilized to clamp the sack 60 to the lint sampler 34 by actuating two clamps 1199, here shown as Referring now to FIGURES 5 and 6, the clamps 1% are clearly shown. The clamps lllll are pivoted'to the frame '52 at points Th2. When the lever 94 is pulled, it rotates in the frame 62 and turns each cam 96. The cams 96 in turn pivot the clamps 1% about the pivot points 162. In this manner, the clamps 1% are moved toward or away from a funnel or chute we beneath the discharge rollers 58. The sack 69 is fitted about the funnel 104 and held thereon when the lever 94 is actuated to move the clamps 1% against the top of 8 the sack 60 and the funnel seen in FIGURE 8.

The lever 94 is also actuates the previously discussed cutter 46. The crank 98 is pivotably attached to the link 1% (see particularly FIGURE 7), which is irr turn attached to the disk 19%. The disk 108 through an appropriate clutch (not shown) is operatively connected to the crank 56, previously discussed with reference to FIG- URES 2 and 3. Therefore, pulling the lever 94 also rotates the crank 93 which moves the link 1536 to rotate the disk H58. Rotation of the disk res thereupon actuates the crank 56 and link 54, to pivot the cutter as, thereby exposing the bulging cutter surface 52.

Still a third function is performed by the lever 94. When the sack 53 is attached, and the cutter 46 rotated for the cutting operation, then the compression roller 42b is pivoted outwardly from the drum all. Particular reference is now made to FIGURE 8, wherein the lever 94 and part of the gearing and pulleys for the drum as, compression rollers 42, guide rollers 33, and discharge rollers are shown. Thus the compression rollers 42 are immediately a tached to the compression roller gears 142, the discharge rollers 53 to the discharge roller gears 15$, and the like. Keyed to the lever 94- is a crank illtl, which is pivotably attached to the link 1212, which in turn is pivotably attached to the bell crank 114 which is pivotably attached to the link 116, which is in turn pivotably attached to the compression roller 42!). The compression roller 32b and its gear 1425: are pivotably attached to the compression roller 42a and its gear 142a, as by the link 118. Therefore, pulling the lever 94 results in pivoting the compression roller 42b and its gear 142-17, as shown by the pivoted position in dotted lines in Fi-GURE 8 and the addition of prime marks. Thus, pulling lever lid rotates crank 11% to 11%, moves link 11?) to 112, rotates bell crank 134 to lie, pulls out link 1116 to Ho, and therefore pivots gear 142:) to 14212 away from the drum.

The funnel tea is best Finally, movement of the lever 9'4 may also reverse the motor as or associated gearing to change the direction of rotation of the drum 4% from compression to ejection of the batt 44-. Likewise, it is obvious that each of the functions of the lever 94 may be performed by separate levers or other means within the skill of the art.

From the foregoing, it is felt that the operation of the present invention as a lint sampler 34 is apparent. Briefly, then, the valve 23 is opened to admit airborne lint 32 to the condenser rollers 36 which remove the air and form a loose batt 44. This batt is firmed and guided to the drum 4h by the guide rollers 38. Thereupon, the batt 44 is compressed about the drum 4% by the compression rollers 42. When the main bale isfinished, the valve 23 is closed and the remainder of the batt id quickly wound and compressed. Thereupon the motor 86 is stopped and the lever 94 pulled. This pivots the compression roller 42]; away from the drum ill; exposes the surface 52 of the cutter 45 to the action compression roller 42a; and clamps the sack 69 to the funnel ltld. Then, through appropriate gearing, the rotation of the roller 42a begins in the opposite direction and cuts the batt 44. The surface 52 of the cutter as is withdrawn and replaced again with surface 54). The compression roller 42c begins to turn in a direction opposite to the drum .6 rotation and leads the cut batt 44 to the discharge rollers 53. The discharge rollers guide the compressed batt 44- into the sack 68. Thereafter, a return of the lever @4 to its original position releases the sack 6% with the compressed sample therein, and prepares the lint sampler 34 for another cycle.

Obviously more or less compression rollers may be utilized than those shown, and the width of the drum increased or decreased as needed, all being within the skill of the art. Likewise, the motor need not be mounted on the frame, nor need it be a motor at all, for the lint sarn ler may be actuated by an existing jackshaft in the co on girl.

When it is desired to u e the present invention as a rotary press for the production of full size bales, it is readily apparent that the type of drum previously discussed is quite adaptable theref r. In this instance, the rotary press would replace the large gin press 22 shown schemically in l-URE l. The rotary press would .e a large number of compressed baits which would eupon be ed together on the platen of a small '5 1'3 press need not be a power- -ine, for reasons that wfll be apparent from anlook at 15. When the rotary press comes the cotton along the curve from a to b, and then press of the present invention have completely ge 86 strolze Hi-D platen press. The no additional outlay to the es are also utilized to band gin platen presses.

[rated for the drum convention.

' are uttin the need for c 5p will 1, 1!, is seen t i ing to Fl is withdrawn from rollers, the compressed batt by contacting the inner in; itself. See FEGURE 12 The double-over bait as a length of /2 the circumference of the th be; produced by the lint atey the circumth onal length .imately 34- inches, the

ess will have a drum rte small. A e to FEGURES 9-13 which show "ent invention and ral are Very similar to the preion rollers 5.: and discharge the drum comprises a series 2'36 which be locked in place 11 which a batt 233 of cotton of retractable seal to form a cit the segments may be unlocked, from the ch ter of col ression rollers :ed d um a sc ematic representais shown, surrounded by rollers 2-32, with the batt .pressed on the drum 2%. Rotation the arrows. T e s gments are shown e drum riate condenser (such as that previously .5 cease to supply more oatt 2e8, further drum 2t, produces a ring-like compressed Fotstion of the P cm 2 ,3 and rollers 255 2 is eupon, re'fe now to FlGURE 11, the 1 segments of the drum th"! are moved inward the ce ter of the drum J and then moved -e f the drum so that the drum n the cluster of compression rollers 2 32., in a manner to be her ter described. Now, the bat. 233 is unsupported in its center.

Referring now to FlGURE l2, the compression rollers 262 are again rotated to elect the compressed batt 208.

The ejection is accomplished by rotating the rollers 2% i lly and downwardly, that is the rollers 2 32 on the 5 left-hand side rotate clockwise and those on the right counterclock e, as shown by the arrows. The batt 2%,

therefore, is A led between the lowermost inwardly rotating com ssion rollers 2%2, doubled over, and ejected downwardl between the discharge rollers 2 34. As mentioned with rewrd to the compression rollers 42, these compression ro is 162 may be knurled, toothed, splined, or the like.

When the segmented drum type rotary press is used as a sain ler, the batt 293 may be placed, as before, in a sack. And, when used as a rotary press, the batts are stacked on a small banding press for tying in a conventional manner.

Thus, a compressed batt may be quickly fabricated and ejected, for the formation No'. that the operation of a segmented drum has been presented, reference is made to FEGURES 9 and 13 for a specific embed at thereof. Each of the segments 2 96 includes a head is whose or surface is curved, so that all of the segments 2% ogor form a circle, as seen in FEGURE 9. On the baclr e or" the heads are, stems 212 are conventionally attached, and the innermost ends of the stems are tapered, shown at 214 in FIGURE 13. Attached to the stems 232 are lugs 21%.

in the center of the drum 2 9 is a tapered hub 213 which is attached to in a concenrio shaft same as that of the the l as n pered end 22 1 of the stem 212. "e end of the tapered is a shoulder 224. S da'oly mounted on the shart 222i) is a disk 226 to w ich are attached suitable guide rings 22%. The guide rings include openings arranged in a radial patsprings 234 which yieldably urge the lugs 216, stems 212-, heads Eli and therefo e the segments radially inwardly. Thus the tapered ends El i of the stems 212 are urged tow d the tapered hub 218.

Immediately behind the is a cup 23% which is attached to the concel rc shaft 222. The outer diameter of the cup 236 is slightly larger than the diameter of the drum when in a locked position as shown in FIGURE 13, and the inner iameter of the cup ass is slightly larger than the diameter of the drum 2% when in an unlocked position as shown in the dotted lines in FIG- l3, for a purpose which will become apparent. About the drum 2 3% when in a locked position are a cluster of compression rollers 232. Conventionally attached to the compression rollers 2-52 are gears such as 23% and 24% whereby the compression rollers 2-52 may be rotated in the same direction for compression and hah of them in the opposite direction for ejection, as mentioned above. Adjacent the drum 2% and opposite the cup 236 is a plate 242 which is rotatably attached to the frame 244, and which has a diameter slightly larger than the drum 2% in a locked posi. n, as does the cup 236. The com- 5 pression rollers and concentric shaft 222 are also journaled in the frame 24%, in a conventional manner.

drum 2% is in a locked position. The space left between the compression rollers 2M and head 210 of the segments 2%, and bounded on the sides by the plate 242 and the cup 2%, is utilized to compress the batt 263 of cotton fiber. As the drum 2%, compression rollers 262, plate 242 and cup are all rotatable, the batt 2&8 being compressed will not snag.

To unlock and retract the drum 2% so that the compressed batt 2% may be ejected, the shaft 229 is moved to the right. The tapered hub 218 engages the disk 226 and moves it back into the cup 236. The final position of the disk 22d when unlocked is shown in dotted lines 226' in FIGURE 13. Likewise, the unlocked position of the tapered hub 218 is shown in dotted lines as 218. As the hub 218 moves to the unlocked position 21%, the tapered ends 214 of the stems 212 are urged radially inwardly by the springs 234 and slide along the tapered hub 2.18. Thus, the diameter of the segmented drum 2% is reduced to less than the inner diameter of the cup 236. When the hub 218 engages the disk 226 and begins to move the disk 226 to its unlocked position 226', the guide rings 228 engage the stems 212 and thereby move the segments 2% to the unlocked position 2%. In this manner the entire segmented drum 2% is reduced in diameter and moved axially into the cup 236, thereby leaving the batt 2&3 intact and unsupported, as shown in FIGURE 11. Thereafter, appropriate rotation of the compression rollers 2% will quickly eject the compressed batt 2%.

The operation and use of the segmented drum 2% is believed to be apparent. Briefly, in summary, the segmented drum is locked by axially moving the hub 218 to the left, whereupon the tapered ends 214 of the stems 212 are moved radially outwardly by the tapered hub 218. This outward movement continues until the shoulder 224- of the hub 21% engages the sides of the stems 212, thereby locking the segmented drum sea. Rotation of the compression rollers 2*82 and drum 2% is commenced, and the batt 263 is wound and compressed upon the drum 2%. When the desired thickness and compression of the batt 208 has been attained, the rotation is ceased. Thereupon the segmented drum 2% is removed from the cluster of compression rollers 2%32, by axial movement of the shaft 22% Thereupon, the stems 212 and thus the segments 2% move radially inwardly along the tapered hub 218, thus reducing the diameter of the drum 2%. Then the disk 226 is engaged by the hub 218 and moved axially to 226, pulling the segments 2% along to 2% by the action of the guide rings 22% on the stems 212. The unsupported batt 263 is quickly ejected without cutting by the inward and downward rotation of the compression rollers 292 and through the discharge rollers 2%. The compressed batt 208 is thereafter sacked as a sample, or laid on a stack of similar batts for banding into a bale. Another batt is quickly fabricated by again locking the drum 2% and repeating the cycle.

Yet another form of drum is contemplated which will produce highly compressed batts of cotton, either for sampling or bale formation. This drum is likewise removable from the cluster of compression rollers and produces an uncut batt similar to that produced by drum 2% above. As the theory of production of a compressed batt the operation of the compression rollers have previously been presented, only a single view of this modification is presented, FIGURE 14, for its general structure will be apparent from the preceding discussion.

Generally, this modification of the invention comprises a drum Silil which is surrounded by a cluster of compression rollers 382. The drum 3% is split, however, into two flanged wheels 394 and 3&6. When the wheels 3% and 3% are butted together a drum is formed, about which is wound and compressed a batt as before. To remove the compressed batt, the wheels 3% and 396 are moved axially apart, and the compressed batt ejected as was the batt 208 in FIGURE 12.

Referring now to FIGURE 14, on the frame 308 in suitable bearings 310 are mounted a series or cluster of compression rollers 3G2. Within the cluster of compression rollers is a split drum Still The drum 3-99 includes wheels Bil-i and 306. The wheels 364 and 366 are mounted on shafts 312 and 314 which are suitably journaled for retational and axial movement. The wheels 3% and 365 include flanges 316 and may be tapered, as shown. When butted together as shown in FIGURE 14, the wheels 3% and 306 form the drum 3%. When the shafts 312 and 314 are pulled apart, in the directions shown by the arrows, the wheels are moved outwardly to the positions shown in dotted lines as 3134' and 3&5. In the positions 394 and 3%, of course, the compressed batt is unsupported and may be quickly ejected.

In use, the split drum 3% is formed by butting the wheels 3&4 and 3% together. Thereupon, the cotton batt is wound about the drum 3% and compressed by the compression rollers 362. The compression area is bounded by the wheels 3% and 3&5, the flanges 316, and the compression roller 3 52. After compression is complete, the rotation of the drum 3% and rollers 3% is stopped. To remove the ring-like batt formed, the shafts 312 and 314 are moved axially apart, thereby moving the wheels 394 and 306 to positions Ed t and 395. The taper of the wheels 3&4 and 3% will ermit the wheels to be easily withdrawn from the compressed batt. Thereupon, the compressed batt is quickly ejected by the opposite rotation of the compression rollers 3132, just as was previously discussed with reference to the segmented drum 2%.

Of course, the segmented drum 2% or the split drum 39%) may be substituted for the drum 4% for use as a lint sampler with attendant minor changes well within the skill of the art. Similarly, any of the various drums may be utilized to produce compressed batts for stacking and banding into bales. Likewise, it is contemplated that additional drum configurations, either retractable or not, will be found suitable for the compression of cotton batts.

Thus it is seen that the present invention provides a simple, yet etfective, means for the formation of highly compressed cotton batts which may be utilized for the formation of bales or as a lint sampler.

As the theory of operation has been previously disclosed, the method of the present invention is believed to be apparent. As mentioned, any of the apparatus embodirnents may be utilized and the method is not intended to be limited to these shown. Briefly, the method of the present invention includes the condensation of airborne lint into a loose fibrous batt. Thereupon, the batt is wound upon a suitable drum and compressed between the drum and a series of compression rollers disposed about the drum. The compressed batt is quite dense, for the reasons previously given with reference to FIGURE 15. The compressed batt is then ejected from between the drum and compression rollers, either by cutting the batt or retracting the drum, and led into a wrapper or sack for use as a sample, or placed on a small banding press with similar compressed batts for the formation of a banded bale.

The present invention, therefore, is well adapted to carry out the objects and attain the ends and advantages mentioned as well as others inherent therein. While presently preferred embodiments of the invention have been given for the purpose of disclosure, numerous changes in the details of construction, and the combination, shape, size, arrangement of parts, and uses may be resorted to without departing from the spirit and scope of the inven tion as hereinafter claimed.

What is claimed is:

1. In a batt compressing rotary press, a rotatable nonadhesive batt winding drum, a series of rotatable compression rollers surrounding and spaced in fixed relationship from the periphery of said drum, means for rotating said drum and rollers in the same surface direction with speed to wind and compress said batt upon said drum between said drum and said compression rollers, means for Withdrawing said drum from amongst said compression rollers, and means for rotating said compression rollers to eject said compressed batt from said rotary press.

2. In a batt compressing rotary press, a rotatable nonadhesive batt winding drum, said drum comprising segments movable radially inwardly, said drum movable axially when said segments are moved radially inwardly, means for moving and locking said drum to a first position wherein said segments are locked radially outwardly and means for moving said drum axially and said segments radially inwardly to a second position, a series of rotatable compression rollers surrounding and spaced in fixed relationship from the periphery of said drum when in said first position, and means for rotating said drum and rollers in the same surface direction with respect to the batt at substantially the same peripheral speed.

3. The invention of claim 2 including means for forming a loose batt and introducing it between one of said compression rollers and said drum, whereby said batt is wound upon said drum and compressed between said drum and said compression rollers, and means for rotating said compression rollers when said drum is in said second position to eject said compressed batt from said rotary press.

4. The invention of claim 3 wherein said forming and introducing means includes a condenser and rotatable guide rollers disposed adjacent said drum when in said first position.

5. In a batt compressing rotary press, a pair of rotatable and symmetrical axially movable non-adhesive wheels, said wheels when butted together forming a batt winding drum, a series of rotatable compression rollers surrounding and spaced in fixed relationship from the periphery of said drum, means for rotating said drum and rollers in the same surface direction with respect to the batt at substantially the same peripheral speed, means for moving said wheels axially apart and without said series of compression rollers, and means to rotate half of said compression rollers in a rotary direction opposite to that of the remaining compression rollers 6. The invention of claim 5 wherein said wheels include flanges.

7. The invention of claim 6 wherein said flanged wheels are tapered.

8. The invention of claim 7 including means for forming and introducing a loose batt between one of said rollers and said drum, and discharge rollers disposed beneath said drum, whereby said batt is wound upon said drum and compressed between said drum and said compression rollers and said wheels moved axially apart and said compression rollers rotated to eject said compressed batt between said discharge rollers for ejection from said rotary press.

9. In a method of compressing a loose fibrous batt, winding said batt upon a drum while maintaining a nonadhesive relationship therebetween, compressing said wound batt between said drum and a series of compression rollers surrounding and spaced in fixed relationship from said drum, withdrawing said drum from within the said compression rollers while maintaining said batt within the said surrounding compression rollers, and rotating said compression rollers to eject said compressed batt as a continuous loop.

References Cited in the file of this patent UNITED STATES PATENTS 27,830 Powell Apr. 10, 1860 446,128 Brown Feb. 10, 1891 529,967 Smith et al Nov. 27, 1894 653,191 Treese July 3, 1900 681,928 Remhart Sept. 3, 1901 731,882 Fordyce June 23, 1903 980,706 Treese Jan. 3, 1911 1,257,798 Brown Feb. 26, 1918 1,333,351 Taft Mar. 9, 1920 1,834,466 Mackenzie Dec. 1, 1931 1,881,774 Mackenzie Oct. 11, 1932 1,988,692 Lanter Ian. 22, 1935 2,313,102 Taylor Mar. 9, 1943 2,320,544 s ns e at 

9. IN A METHOD OF COMPRESSING A LOOSE FIBROUS BATT, WINDING SAID BATT UPON A DRUM WHILE MAINTAINING A NONADHESIVE RELATIONSHIP THEREBETWEEN, COMPRESSING SAID WOUND BATT BETWEEN SAID DRUM AND A SERIES OF COMPRESSION ROLLERS SURROUNDING AND SPACED IN FIXED RELATIONSHIP FROM SAID DRUM, WITHDRAWING SAID DRUM FROM WITHIN THE SAID COMPRESSION ROLLERS WHILE MAINTAINING SAID BATT WITHIN THE SAID SURROUNDING COMPRESSION ROLLERS, AND ROTATING 